Device for maintaining biasing state of biasing force application means used in seat belt retractor

ABSTRACT

A device for maintaining a biasing state of a biasing force application means used in a seat belt retractor. The inner end (8a) of a power spring (8) of the biasing force application means (5) is retained by a bush (9), and the outer end (8b) of the power spring (8) is retained by a retaining portion (10d) of a spring casing (10). In a state where the biasing force application means (5) is formed as a subassembly and the power spring (8) has been wound up by a predetermined amount in a direction in which a webbing (3) is unwound, a spring pin (12) is attached to the subassembly so that a pair of rotation preventing arms (12a) and (12b) of the spring pin (12) pierce through small holes (11b and 11c) provided in a cover (11), either of grooves (9b and 9c) and either of grooves (9 d and 9e), which are provided in the bush (9), and small holes (10b and 10c) provided in the spring casing (10), thereby enabling the power spring (8) to be readily maintained in the wound-up state.

BACKGROUND OF THE INVENTION

The present invention relates to a biasing force application means for biasing a reel shaft in a direction for winding up a webbing in a seat belt retractor employed in a seat belt system which is provided on a vehicle, for example, an automobile, for the purpose of protecting an occupant when an emergency situation occurs by locking the reel shaft from rotating to thereby prevent the webbing from being pulled out. More particularly, the present invention relates to a device for maintaining a biasing state of the biasing force application means that is formed as a subassembly at the time of assembling the seat belt retractor.

Automobiles and other vehicles have formerly been equipped with seat belt system for protecting occupants. In general, a seat belt system has a seat belt retractor. The seat belt retractor has a reel shaft for winding up a webbing. The reel shaft is constantly biased in a direction for winding up the webbing by a relatively small biasing force from a biasing force application means having a spring.

Accordingly, in a typical seat belt retractor of the type described above, the webbing is wound up on the reel shaft under normal circumstances, and when it is necessary to unwind the webbing in order to fasten the seat belt, for example, the webbing can be unwound as desired with a relatively small pulling force. At the time of occurrence of such an emergency situation that a high degree of deceleration acts on the vehicle, the reel shaft is locked from rotating to thereby prevent the webbing from being pulled out by the inertial movement of the occupant's body.

In general, the biasing force application means, which constantly biases the reel shaft, is mounted on the outer surface of one side wall of a U-shaped frame for rotatably supporting the reel shaft, and it comprises a power spring, which is a spiral spring for producing biasing force, a bush which is engaged with the inner end of the power spring and transmits the biasing force of the power spring to the reel shaft, a spring casing which accommodates the power spring and the bush and which is engaged with the outer end of the power spring, and a cover which covers the spring casing.

Incidentally, when the seat belt retractor is to be assembled, the biasing force application means is usually assembled in advance as a subassembly, and this subassembly is attached to the frame. When the biasing force application means is in the subassembled state, it is necessary to apply the biasing force of the spring to the reel shaft in the webbing winding direction at all times. Therefore, the power spring needs to be held in a state where it has been wound up by a predetermined amount in the webbing unwinding direction. Accordingly, a device for maintaining the biasing state of the biasing force application means has heretofore been employed when the seat belt retractor is assembled.

In the conventional biasing state maintaining device for the biasing force application means, a relatively large hole is opened in a portion of the cover that faces the bush, and in a state where the spring casing, the bush, the power spring and the casing have been assembled with the power spring wound up by a predetermined amount in the webbing unwinding direction, a stopper is inserted into the hole in the cover and engaged with the bush and the spring casing so as to prevent rotation of the bush in at least a direction in which the power spring is unwound, thereby holding the power spring in the wound-up state.

Then, the subassembled biasing force application means is mounted on the frame with the bush fitted to the rotating shaft of the reel shaft so that the bush is unable to rotate relative to the rotating shaft. Thereafter, the stopper is removed, and the hole in the cover is closed with a lid. Thus, the assembling of the biasing force application means is completed.

However, with the conventional biasing state maintaining device for the biasing force application means, the stopper must be engaged with the bush and the spring casing. Therefore, the assembling operation is relatively complicated and requires time and labor. In addition, there is likelihood that the stopper will disengage and fall from the hole of the casing while the subassembled biasing force application means is being transported to the seat belt retractor assembly line. Thus, it is relatively difficult to maintain the biasing state of the biasing force application means.

Further, it is necessary to carry out the operation of removing the stopper and closing the hole of the cover with the lid after the subassembly has been mounted on the frame. Thus, the prior art requires a large number of parts as well as a large number of manufacturing operation steps.

SUMMARY OF THE INVENTION

It is an object of the present invention to provide a biasing state maintaining device for a biasing force application means used in a seat belt retractor, which is designed so that the biasing state of the biasing force application means can readily be maintained, and it is also possible to reduce the number of parts required as well as the number of operation steps required.

To attain the above-described object, the present invention provides a device for maintaining a biasing state of a biasing force application means used in a seat belt retractor. The biasing force application means includes a bush fitted to a reel shaft so as to be unable to rotate relative to it, a spring casing for accommodating the bush, a cover for covering the spring casing, and a spring accommodated in the spring casing and retained at the inner end thereof by the bush and at the outer end thereof by the spring casing so that the reel shaft is biased by spring force from the spring so as to rotate in a direction for winding up a webbing. The biasing state maintaining device includes a pair of small holes formed in the spring casing, a predetermined number of grooves formed in the bush, a pair of small holes formed in the cover, and a rotation preventing member formed from an elastic material and having a pair of rotation preventing arms capable of piercing through the small holes and the grooves. The rotation preventing member is attached to the biasing force application means in a state where the spring has been wound up by a predetermined amount so that the pair of rotation preventing arms pierce through the small holes of the spring casing, two of the grooves of the bush and the pair of small holes of the cover, thereby maintaining the spring in the wound-up state.

The rotation preventing member may be a spring pin formed by bending a single elastic wire material in a U-shape.

In the biasing state maintaining device according to the present invention, the rotation preventing member is attached to the biasing force application means, which is in a state of subassembly with the power spring wound up by a predetermined amount in a webbing unwinding direction so that the pair of rotation preventing arms thereof pierce through the pair of small holes of the cover, two of the grooves of the bush and the pair of small holes of the spring casing, thereby enabling the power spring to be readily held in the wound-up state.

Further, since the cover need not be provided with a large hole, there is no need for a lid which has heretofore been needed to close such a hole, and hence it is unnecessary to carry out an operation for mounting a lid. Thus, it is possible to reduce the number of parts required as well as the number of manufacturing operation steps required in comparison to the conventional seat belt retractor.

Further, according to the present invention, since the rotation preventing member is formed from a single elastic wire material, the biasing state maintaining device can be formed with ease and at reduced cost.

Still other objects and advantages of the invention will in part be obvious and will in part be apparent from the specification.

The invention accordingly comprises the features of construction, combinations of elements, and arrangement of parts which will be exemplified in the construction hereinafter set forth, and the scope of the invention will be indicated in the claims.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1A is an exploded perspective view of a central portion of one embodiment of a seat belt retractor according to the present invention.

FIG. 1B is an exploded perspective view of a left-hand portion of the embodiment of the seat belt retractor according to the present invention.

FIG. 1C is an exploded perspective view of a right-hand portion of the embodiment of the seat belt retractor according to the present invention.

FIG. 2 is a side view of the seat belt retractor of the embodiment in an assembled state, as seen from the right-hand side thereof, with a cover removed therefrom.

FIG. 3 is a sectional view taken along the line III-III in FIG. 2, showing the assembled state of the seat belt retractor of the embodiment.

FIG. 4 is a fragmentary sectional view taken along the line IV--IV in FIG. 3, showing the assembled state of the seat belt retractor of the embodiment.

FIG. 5 is a side view of a frame employed in the embodiment, as seen from the right-hand side thereof.

FIG. 6 is a side view of the frame employed in the embodiment, as seen from the left-hand side thereof.

FIG. 7 is a front view of a reel shaft employed in the embodiment.

FIGS. 8(a) and 8(b) are side views of the reel shaft employed in the embodiment, as seen from the right-hand side thereof.

FIGS. 9(a) and 9(b) and side views of the reel shaft employed in the embodiment, as seen from the left-hand side thereof.

FIG. 10 is a side view of a bush employed in the embodiment, as seen from the left-hand side thereof.

FIGS. 11(a) and 11(b) are views showing a spring casing employed in the embodiment, in which FIG. 11(a) is a side view of the spring casing as seen from the right-hand side thereof, and FIG. 11(b) is a sectional view taken along the line XIB--XIB in FIG. 11(a).

FIGS. 12(a) and 12(b) are views showing a cover employed in the embodiment, in which FIG. 12(a) is a side view of the cover as seen from the left-hand side thereof, and FIG. 12(b) is a sectional view taken along the line XIIB--XIIB in FIG. 12(a).

FIG. 13 shows a spring pin employed in the embodiment.

FIG. 14 is a side view of a lock gear first cover employed in the embodiment, as seen from the left-hand side thereof.

FIG. 15 is a side view of the lock gear first cover employed in the embodiment, as seen from the right-hand side thereof.

FIGS. 16(a), 16(b) and 16(c) are views showing a lock gear employed in the embodiment, in which FIG. 16(a) is a side view of the lock gear as seen from the right-hand side thereof, FIG. 16(b) is a sectional view taken along the line XVIB--XVIB in FIG. 16(a), and FIG. 16(c) is a sectional view taken along the line XVIC--XVIC in FIG. 16(a).

FIGS. 17(a) and 17(b) are views showing an inertia member employed in the embodiment, in which FIG. 17(a) is a side view of the inertia member as seen from the left-hand side thereof, and FIG. 17(b) is a sectional view taken along the line XVIIB--XVIIB in FIG. 17(a).

FIGS. 18(a), 18(b) and 18(c) are views showing a main pawl employed in the embodiment, in which FIG. 18(a) is a side view of the main pawl as seen from the left-hand side thereof, FIG. 18(b) is a front view of the main pawl, and FIG. 18(c) is a side view of the main pawl as seen from the right-hand side thereof.

FIGS. 19(a), 19(b) and 19(c) are views showing a joint pin employed in the embodiment, in which FIG. 19(a) is a front view of the joint pin, FIG. 19(b) is a sectional view taken along the line XIXB--XIXB in FIG. 19(a), and FIG. 19(c) is a side view of the joint pin as seen from the left-hand side thereof.

FIGS. 20(a), 20(b), and 20(c) are views showing a backup pawl employed in the embodiment, in which FIG. 20(a) is a side view of the backup pawl as seen from the left-hand side thereof, FIG. 20(b) is a front view of the backup pawl, and FIG. 20(c) is a side view of the backup pawl as seen from the right-hand side thereof.

FIG. 21(a) and 21(b) are views showing a lock gear second cover employed in the embodiment, in which FIG. 21(a) is a side view of the lock gear second cover as seen from the left-hand side thereof, and FIG. 21(b) is a view as seen from the direction of the arrow XXIB in FIG. 21(a).

FIG. 22 is a partly-cutaway side view of a deceleration sensing means employed in the embodiment.

FIGS. 23(a) and 23(b) are views showing a casing, a lever and a pawl of the deceleration sensing means, in which FIG. 23(a) is a front view thereof, and FIG. 23(b) is a partly-cutaway side view of the deceleration sensing means as seen from the right-hand side thereof.

FIGS. 24(a), 24(b) and 24(c) are views showing an inertia member of the deceleration sensing means, in which FIG. 24(a) is a plan view of the inertia member, FIG. 24(b) is a partly-cutaway front view of the inertia member, and FIG. 24(c) is a bottom view of the inertia member.

FIGS. 25(a), 25(b) and 25(c) are views showing a webbing guide employed in the embodiment, in which FIG. 25(a) is a plan view of the webbing guide, FIG. 25(b) is a side view of the webbing guide as seen from the left-hand side thereof, and FIG. 25(c) is a sectional view taken along the line XXVC--XXVC in FIG. 25(a).

FIGS. 26A(I)(a) through 26A(I)(d) and FIGS. 26A(II)(a) through 26A(II)(d) illustrates one part of e operation of the main and backup pawls in the embodiment.

FIGS. 26B(I)(c) through 26A(I)(g) and FIGS. 26B(II)(c) through 26B(II)(h) illustrates the main and, backup pawls in the embodiment.

FIGS. 27(a) and 27(b) illustrates the operation of the main pawl and the lock gear which takes place when the main pawl performs a self-lock action, in which FIG. 27(a) shows the main pawl and the lock gear when the main pawl is in a standby position, and FIG. 27(b) shows them when the main pawl is in a lock position.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

FIGS. 1A to 1C are exploded perspective views showing one embodiment of a seat belt retractor according to the present invention. FIG. 1A shows a central portion of the embodiment, while FIG. 1B shows a left-hand portion thereof, and FIG. 1C shows a right-hand portion thereof. An exploded perspective view showing the whole of the embodiment is formed by combining together FIGS. 1A, 1B and 1C with the imaginary lines A₁, B₁, C₁ and D₁ in FIG. 1A matched with the imaginary lines A₂, B₂, C₂ and D₂ in FIG. 1B, respectively, and with the imaginary lines E₁, F₁, C₁, G₁ and H₁ in FIG. 1A matched with the imaginary lines E₃, F₃, C₃, G₃ and H₃ in FIG. 1C, respectively. FIGS. 2 to 4 show the seat belt retractor of this embodiment which is in an assembled state. FIG. 2 is a side view of the seat belt retractor as seen from the right-hand side thereof with a cover removed therefrom. FIG. 3 is a sectional view taken along the line III--III in FIG. 2. FIG. 4 is a fragmentary side view of the arrangement shown in FIG. 3, as seen from the left-hand side thereof with a biasing force application means 5 removed therefrom.

As shown in FIGS. 1A to 4, the seat belt retractor 1 in this embodiment includes a U-shaped frame 2 having a pair of right- and left-hand side walls 2a and 2b, which are connected together through a connecting member 2c, thereby reinforcing the frame 2. The right-hand side wall 2a is formed with a circular hole 2d, as shown in FIG. 5. Similarly, the left-hand side wall 2b is formed with a circular hole 2e, as shown in FIG. 6. In addition, the inner peripheral surface of the hole 2d in the right-hand side wall 2a is formed with a predetermined number of sawtooth-shaped teeth 2f over the entire circumference thereof. Similarly, the inner peripheral surface of the hole 2e in the left-hand side wall 2b is formed with a predetermined number of sawtooth-shaped teeth 2g over the entire circumference thereof. The phase of the left-hand teeth 2g is advanced a predetermined angle (e.g., 3°) in a webbing unwinding direction α with respect to the phase of the right-hand teeth 2f. The teeth 2f and 2g have the same triangular cross-sectional configuration. The surface of each tooth that faces the webbing unwinding direction α has a relatively steep slope, whereas the surface of the tooth that faces a webbing winding direction β has a relatively gentle slope.

The surfaces of these teeth 2f and 2g that have a relatively steep slope are shaped so that after main and backup pawls 17 and 20 have been guided by cam holes 14m and 14n to respective standby positions where teeth 17d and 20d of the pawls 17 and 20 begin to engage with the corresponding teeth 2f and 2g, the main and backup pawls 17 and 20 are allowed to pivot to respective lock positions where the teeth 17d and 20d are completely engaged with the teeth 2f and 2g, that is, the main and backup paws 17 and 20 are each allowed to perform a self-lock action. The details of the self-lock action will be described later.

Further, the left-hand side wall 2b is provided with three engagement holes 2h, 2i and 2j and a guide hole 2q which comprises an elongated hole. The right-hand side wall 2a is provided with four engagement holes 2k, 2m, 2n and 2r and a guide hole 2p which comprises an elongated hole. In addition, the right-hand side wall 2a has an engagement projection 2s projecting upwardly from the upper end thereof.

As shown in FIG. 3, a reel shaft 4 for winding up a webbing 3 is disposed between the right- and left-hand side walls 2a and 2b of the frame 2. Referring to FIG. 7, the reel shaft 4 comprises a central webbing winding portion 4a, circular flanges 4b and 4c, which are formed at the right and left ends, respectively, of the webbing winding portion 4a so as to guide the webbing 3 when wound up, a first rotating shaft 4d that is provided in the center of the flange 4b so as to project axially outward, and a second rotating shaft 4e that is provided in the center of the flange 4c in coaxial relation to the first rotating shaft 4d. The webbing winding portion 4a is provided with a diametrical through-hole 4f into which one end of the webbing 3 is inserted and retained so that the webbing 3 can be wound up. One end of the through-hole 4f is formed with a relatively wide width. Accordingly, the through-hole 4f is designed in the form of a stepped-hole, which has steps 4g, so that the end of the webbing 3 is retained by the steps 4g.

The reel shaft 4 may be formed from PF die cast aluminum, for example.

As shown in FIGS. 8(a) and 8(b), the right-hand flange 4b is provided with a first recess 4h for accommodating a pawl spring 18 (shown in FIG. 1A), a second recess 4i in which is disposed a pawl portion 17c of a main pawl 17 (shown specifically in FIG. 18, described later), a load bearing portion 4k that is formed with a load bearing surface 4j for receiving a load applied to the pawl portion 17c of the main pawl 17, an axial through-hole 4m in which a joint pin 19 is rotatably fitted, and a third circular recess 4n that is formed at one end of the through-hole 4m in concentrical relation to it. The first, second and third recesses 4h, 4i and 4n are axially recessed most deeply relative to the surface of the outer peripheral edge 4p of the flange 4b. The load bearing portion 4k is axially recessed relative to the surface of the outer peripheral edge 4p of the flange 4b, shallower than the recesses 4h, 4i and 4n. Accordingly, a step 4q is formed between the second recess 4i and a portion of the outer peripheral edge 4p of the flange 4b where the first recess 4h is formed. Similarly, steps 4r and 4s are respectively formed between the outer peripheral edge 4p of the flange 4b and the load bearing portion 4k, and between the second recess 4i and the load bearing portion 4k. The load bearing surface 4j is formed from a circular arc of a predetermined length which is a part of a circle concentrical with respect to the through-hole 4m.

Further, the outer peripheral surface of the flange 4b is formed with three circumferentially equally spaced right-hand guide portions 4t for axially guiding the reel shaft 4 relative to the right-hand side wall 2a when the reel shaft 4 is disposed in between the right- and left-hand side walls 2a and 2b. The size of the right-hand guide portions 4t is so set that the flange 4b cannot readily pass through the holes 2d and 2e in the right- and left-hand side walls 2a and 2b. However, the right-hand guide portions 4t each have predetermined number of teeth 4t₁. The teeth 4t₁ are similar to but a little smaller than the teeth 2f and 2g formed on the right- and left-hand side walls 2a and 2b. Accordingly, when the teeth 4t₁ are matched with the teeth 2f or 2g, the flange 4b having the right-hand guide portions 4t can pass through the holes 2d and 2e.

Further, the distal end of the first rotating shaft 4d is defined as a small-diameter portion 4d₁, which is rotatably fitted to and supported by a small hole 13n provided in a lock gear first cover 13, as described later.

In addition, as shown in FIGS. 9(a) and 9(b), the left-hand flange 4c is provided with a fourth recess 4u in which is disposed a pawl portion 20c of a backup pawl 20 (shown specifically in FIG. 20, described later), a load bearing portion 4w that is formed with a load bearing surface 4v for receiving a load applied to the pawl portion 20c of the backup pawl 20, an axial through-hole 4m in which the joint pin 19 is rotatably fitted, and a fifth circular recess 4x that is formed at one end of the through-hole 4m in concentrical relation to it. The fourth and fifth recesses 4u and 4x are axially recessed most deeply relative to the surface of the outer peripheral edge 4y of the flange 4c. The load bearing portion 4w is axially recessed relative to the surface of the outer peripheral edge 4y of the flange 4c, shallower than the recesses 4u and 4x. Accordingly, a step 4z is formed between the fourth recess 4u and the outer peripheral edge 4y of the flange 4c. Similarly, steps 4A and 4B are respectively formed between the outer peripheral edge 4y of the flange 4c and the load bearing portion 4w, and between the fourth recess 4u and the load bearing portion 4w. The load bearing surface 4v is formed from a circular arc of a predetermined length which is a part of a circle concentrical with respect to the through-hole 4m.

The outer peripheral surface of the flange 4c is also formed with three circumferentially equally spaced left-hand guide portions 4D for axially guiding the reel shaft 4 relative to the left-hand side wall 2b when the reel shaft 4 is disposed in between the right- and left-hand side walls 2a and 2b. The size of the left-hand guide portions 4D is so set that the flange 4c cannot readily pass through the holes 2d and 2e in the right- and left-hand side walls 2a and 2b. However, the left-hand guide portions 4D each have a predetermined number of teeth 4D₁. The teeth 4D₁ are similar to but a little smaller than the teeth 2f and 2g formed on the right- and left-hand side walls 2a and 2b. Accordingly, when the teeth 4D₁ are matched with the teeth 2f or 2g, the flange 4c having the left-hand guide portions 4D can pass through the holes 2d and 2e.

Further, the second rotating shaft 4e, which projects axially from the flange 4c, has a distal end portion 4e₁ with a circular cross-sectional configuration. The root portion 4e 2 of the second rotating shaft 4e has a polygonal (square in this embodiment) cross-sectional configuration.

As will be clear from FIG. 7, the through-hole 4m extends not only through the flanges 4b and 4c but also through the central webbing winding portion 4a axially. In other words, the through-hole 4m extends axially through the reel shaft 4.

As shown in FIGS. 1B and 3, the left-hand side wall 2b has a biasing force application means 5 attached thereto for giving the reel shaft 4 force for winding up the webbing 3. Further, a seat belt lock activating means 6 is attached to the right-hand side wall 2a, as shown in FIGS. 1A, 1C and 3. In addition, the right-hand side wall 2a is provided with a deceleration sensing means 7, as shown in FIGS. 1C and 3. When a predetermined degree of deceleration acts on the vehicle, the deceleration sensing means 7 senses the deceleration and activates the seat belt lock activating means 6.

The biasing force application means 5 comprises a power spring 8, which is a spiral spring, a bush 9 to which the inner end 8a of the power spring 8 is connected to apply spring force thereto, a spring casing 10 to which the outer end 8b of the power spring 8 is secured and which accommodates the power spring 8, and a cover 11 which is attached to the spring casing 10 to cover the power spring 8.

As shown in FIG. 10, the center of the bush 9 is provided with an axially extending through-hole 9a which can be fitted with the root portion 4e₂ of the second rotating shaft 4e of the reel shaft 4. The through-hole 9a has the same polygonal cross-sectional configuration as that of the root portion 4e₂ of the second rotating shaft 4e. The bush 9 is further provided with four grooves 9b, 9c, 9d and 9e of U-shaped cross-section which open in the outer peripheral surface thereof. Among these grooves, the grooves 9b and 9d are disposed diametrically opposite to each other with respect to the center of the bush 9, and so are the grooves 9c and 9e. These grooves are pierced with a spring pin 12 (shown in FIG. 1B), as described later. Although in this embodiment the bush 9 is formed with four grooves 9b, 9c, 9d and 9e, it should be noted that the present invention is not necessarily limited thereto and that the bush 9 may be provided with a proper number of grooves. The bush 9 is further provided with a retaining groove 9f in which the inner end 8a of the spring 8 is fitted and retained.

The bush 9 is connected to the second rotating shaft 4e so as to be unable to rotate relative to it by fitting the hole 9a with the root portion 4e₂ of the second rotating shaft 4e, thereby allowing the spring force of the spring 8 to act on the reel shaft 4 through the bush 9 in the webbing winding direction β at all times.

As shown in FIGS. 11(a) and 11(b), the spring casing 10 has a hole 10a provided in an approximately central portion thereof for rotatably fitting the root portion 4e₂ of the second rotating shaft 4e of the reel shaft 4. The spring casing 10 further has a pair of small holes 10b and 10c which are provided at respective positions which face each other across the hole 10a. The small holes 10b and 10c are pierced with the spring pin 12. In addition, a retaining portion 10d which retains the outer end 8b of the spring 8 is provided near the outer peripheral edge of the spring casing 10.

As shown in FIGS. 12(a) and 12(b), the cover 11 has a hole 11a provided in an approximately central portion thereof for rotatably supporting the distal end portion 4e₁ of the second rotating shaft 4e of the reel shaft 4. The cover 11 further has a pair of small holes 11b and 11c which are provided at respective positions which face each other across the hole 11a. The small holes 11b and 11c are pierced with the spring pin 12. In addition, three engagement projections 11d, 11e and 11f are provided on a flange formed at one end of the cover 11. These projections 11d, 11e and 11f are fitted into and engaged with the corresponding engagement holes 2h, 2i and 2j, which are provided in the left-hand side wall 2b of the frame 2, thereby allowing the biasing force application means 5 to be removably attached to the left-hand side wall 2b of the frame 2.

Incidentally, when the seat belt retractor is to be assembled, the biasing force application means 5 is assembled in advance as a subassembly, and this subassembly is attached to the left-hand side wall 2b of the frame 2. More specifically, the power spring 8 is accommodated in the spring casing 10, and the inner end 8a of the power spring 8 is fitted in and retained by the retaining groove 9f of the bush 9, while the outer end 8b of the power spring 8 is retained by the retaining portion 10d of the spring casing 10. Further, the cover 11 is attached to the spring casing 10 so as to cover the power spring 8, thereby forming a subassembly of the biasing force application means 5.

When the biasing force application means 5 is in the subassembled state, the power spring 8 needs to be held in a state where it has been wound up by a predetermined amount in the webbing unwinding direction α in order to apply spring force to the reel shaft 4 in the webbing winding direction β at all times. For this purpose, the spring pin 12 as shown in FIG. 1B is employed in this embodiment.

As shown in FIG. 13 in detail, the spring pin 12 is formed by bending a single elastic wire material in an approximately U-shape having two rotation preventing arms 12a and 12b. When the biasing force application means 5 is in the subassembled state, the power spring 8 is wound up by a predetermined amount, and the spring pin 12 is attached to the subassembly so that the rotation preventing arms 12a and 12b pierce through the small holes 11b and 11c of the spring cover 11, either of the grooves 9b and 9c and either of the grooves 9d and 9e, which are provided in the bush 9, and the small holes 10b and 10c of the spring casing 10, as shown in FIG. 1B, thereby preventing undesired unwinding of the power spring 8.

In this case, the rotation preventing arms 12a and 12b are engaged with the small holes 10b, 10c, 11b and 11c and the grooves 9b, 9c, 9d and 9c relatively firmly by the unwinding force of the power spring 8, and at the same time, the rotation preventing arms 12a and 12b are elastically engaged with the small holes 10b, 10c, 11b and 11c by the elastic force of the spring pin 12. Therefore, there is no likelihood of the spring pin 12 readily falling off when the subassembly is transported to the seat belt retractor assembly line.

The subassembled biasing force application means 5 is attached to the frame 2 by fitting the engagement projections 11d, 11e and 11f of the cover 11 into the corresponding engagement holes 2h, 2i and 2j, which are provided in the left-hand side wall 2b of the frame 2. In a state where the biasing force application means 5 is attached to the frame 2, the root portion 4e₂ of the second rotating shaft 4e of the reel shaft 4 extends through the through-hole 9a of the bush 9 so as to be unable to rotate relative to it, while the distal end portion 4e₁ of the second rotating shaft 4e is rotatably supported by the hole 11a of the cover 11. In other words, the hole 11 of the cover 11 serves as a bearing for the reel shaft 4.

Then, one end of the webbing 3 is connected to the webbing winding portion 4a of the reel shaft 4. Thereafter, the spring pin 12 is removed. Thus, the reel shaft 4 is rotated by the restoring force of the power spring 8, thereby allowing the webbing 3 to be wound up on the reel shaft 4.

Thus, in the biasing state maintaining device for the biasing means in this embodiment, arranged as described above, in a state where the power spring 8 of the subassembled biasing force application means 5 has been wound up by a predetermined amount, the spring pin 12 is attached to the subassembly so that the rotation preventing arms 12a and 12b pierce through the small holes 11b and 11c of the spring cover 11, either of the grooves 9b and 9c and either of the grooves 9d and 9e, which are provided in the bush 9, and the small holes 10b and 10c of the spring casing 10, as shown in FIG. 1B. Thus, it is possible to readily form a subassembly of the biasing force application means 5 in which the power spring 8 is held in the wound-up state.

In this embodiment, the cover 11 need not be provided with a large hole, and hence there is no need for a lid to close such a hole and a lid mounting operation. Thus, it is possible to reduce the number of parts required as well as the number of manufacturing operation steps required in comparison to the conventional seat belt retractor.

Further, in this embodiment, the distal end portion 4e₁ of the second rotating shaft 4e is rotatably supported by the hole 11a of the cover 11. Therefore, the length of the bush 9 can be reduced in comparison to the structure in which the bush is rotatably supported by a bearing portion of the frame as in the conventional retractor.

In the meantime, the seat belt lock activating means 6 comprises: a lock gear first cover 13 which is secured to the right-hand side wall 2a of the frame 2; a lock gear 14; an inertia member 15 which is rockably attached to the lock gear 14; a control spring 16 which is disposed between the lock gear 14 and the inertia member 15; a main pawl 17 which has one end thereof pivotably supported in the third recess 4n, which is formed in the flange 4b of the reel shaft 4, and the other end of which forms an engagement portion that is disposed in the second recess 4i ; a pawl spring 18 which is accommodated in the first recess 4h of the reel shaft 4 and compressedly loaded in between the reel shaft 4 and the main pawl 17; a joint pin 19 which extends through the axial hole 4m of the reel shaft 4; a backup pawl 20 which is connected to one end of the joint pin 19 and pivotably supported at one end thereof in the fifth recess 4x, which is formed in the flange 4c of the reel shaft 4, and the other end of which forms an engagement portion that is disposed in the fourth recess 4u ; and a lock gear second cover 21 which is fitted to and supported by the right-hand side wall 2a of the frame 2 so as to cover the lock gear first cover 13, the lock gear 14, the inertia member 15, the main pawl 17, the joint pin 19, and the deceleration sensing means 7.

Further, the seat belt retractor 1 has a webbing guide 22 for guiding the webbing 3.

As shown in FIGS. 14 and 15, the lock gear first cover 13 has a relatively large through-hole 13a. The inner peripheral surface of the through-hole 13a is formed with a predetermined number of teeth 13c over the entire circumference thereof. The annularly disposed teeth 13c have a triangular cross-sectional configuration in which the direction α is a substantially vertical surface, whereas, the surface thereof which faces the webbing winding direction β is a relatively gentle slope. Further, the lock gear first cover 13 has three engagement projections 13d, 3e and 13f provided on a side thereof which faces the right-hand side wall 2a of the frame 2, as shown in FIG. 14. These engagement projections 13d, 13e and 13f are fitted into the engagement holes 2k, 2m and 2n, respectively, which are formed in the right-hand side wall 2a, thereby allowing the lock gear first cover 13 to be removably attached to the frame 2.

As shown in FIG. 15, the lock gear first cover 13 is provided with a portion 13g for accommodating the deceleration sensing means 7, which opens to the side reverse to the side where the engagement projections 13d, 13e and 13f are provided. The inner wall of the accommodating portion 13g is provided with a pair of guide members 13h and 13i that guide the deceleration sensing means 7 in a direction perpendicular to the plane of FIG. 15 and that fixedly support the deceleration sensing means 7. The mutually opposing surfaces of the guide members 13h and 13i are formed with respective recesses 13j and 13k of trapezoidal cross-section which extend longitudinally of the guide members 13h and 13i. In other words, the side walls 13j₁, 13j₂, 13k₁ and 13k₂ of the recesses 13j and 13k have slant surfaces.

In addition, an approximately cross-shaped side wall 13m is formed on the lock gear first cover 13 on the side thereof which is reverse to the side where the engagement projections 13d, 13e and 13f are provided. The side wall 13m is so designed that the intersection of two crossing portions of the side wall 13m is substantially coincident with the center of the circle that is defined by the annularly disposed teeth 13c. The intersection of the side wall 13m is provided with a small hole 13n at a position which is coincident with the center of the annularly disposed teeth 13c. The small hole 13n is fitted with the small-diameter end portion 4d₁ of the first rotating shaft 4d of the reel shaft 4 rotatably with substantially no gap left therebetween, thereby allowing the first rotating shaft 4d to be rotatably supported by the small hole 13n.

As shown in FIG. 16(a), the lock gear 14 comprises a circular flat plate portion 14a, and an annular flange 14b that is formed around the outer peripheral edge of the flat plate portion 14a. The outer peripheral surface of the flange 14b is formed with a predetermined number of teeth 14c. The teeth 14c each have a triangular cross-sectional configuration in which the surface of each tooth 14c which faces the webbing unwinding direction α is a relatively gentle slope, whereas, the surface thereof which faces the webbing winding direction β is a substantially vertical surface.

As shown in FIGS. 16(a) and 16(b), the flat plate portion 14a has a spring retaining member 14d provided on the left-hand side thereof (as viewed in FIG. 16(b); the side that is surrounded with the flange 14b ) for supporting one end of the control spring 16. The spring retaining member 14d is provided with a spring guide portion 14e that projects parallel to the flat plate portion 14a. Further, the flat plate portion 14a is provided with a shaft 14f for rockably supporting the inertia member 15, as described later. An arcuate fall preventing member 14g is provided adjacent to the shaft 14f.

As shown in FIG. 16(c), the fall preventing member 14g has a retaining projection 14g₁ formed on the distal end thereof. The retaining projection 14g₁ has a slant surface at the upper end thereof and projects a little toward the shaft 14f. Accordingly, when fitted onto the shaft 14f, the inertia member 15 presses the slant surface of the retaining projection 14g₁, so that the fall preventing member 14g is elastically deformed so as to enlarge a little the gap between the shaft 14f and the fall preventing member 14g. Thus, the inertia member 15 rides over the retaining projection 14g₁ and is accommodated in the space defined between the shaft 14f and the fall preventing member 14g. In this state, if the inertia member 15 is urged to move axially upward as viewed in FIG. 16(c), the axial movement is prevented by the retaining projection 14g₁. Thus, the inertia member 15 is prevented from coming off the shaft 14f. However, since the amount to which the retaining projection 14g₁ projects is so small that the inertia member 15 and the retaining projection 14g₁ engage each other lightly, the inertia member 15 can readily ride over the retaining projection 14g₁ and come off the shaft 14f when a relatively small external force is applied to the inertia member 15 in a direction in which it comes off the shaft 14f. The fall preventing member 14g allows the inertia member 15 to be readily attached to and removed from the shaft 14f and also enables the inertia member 15 to be reliably supported by the shaft 14 in a rockable state.

In addition, the flat plate portion 14a is provided with a first stopper 14h and a second stopper 14i and further has a tubular rotating shaft 14j axially projecting from the center of the flat plate portion 14a. It should be noted that the bore of the tubular rotating shaft 14j is pierced with the first rotating shaft 4d of the reel shaft 4 so that the rotating shaft 14j is rotatable about the first rotating shaft 4d.

Further, the flat plate portion 14a is provided with first, second and third cam holes 14k, 14m and 14n, which extend through the flat plate portion 14a and have predetermined configurations. As shown in FIG. 16(b), the cam holes 14k, 14m and 14n are made greater than the flat plate portion 14a in the wall thickness so that cam followers which are fitted in these cam holes are guided effectively and reliably and the peripheral edges of the cam holes are reinforced. The cam profiles of the second and third cam holes 14m and 14n will be detailed later. The first cam hole 14k is formed as a circular arc centered at the rotating shaft 14j.

On the right-hand side (as viewed in FIG. 16(b); the side that is not surrounded with the flange 14b ) of the flat plate portion 14a is provided with a spring retaining member 14p for supporting one end of the pawl spring 18. The spring retaining member 14p is provided with a spring guide portion 14q which projects parallel to the flat plate portion 14a.

As shown in FIGS. 17(a) and 17(b), the inertia member 15 is formed in an approximately C shape from a flat plate. The inertia member 15 is formed in the center thereof with a boss portion 15b having a hole 15a. Further, a pawl 15c is formed at one end of the inertia member 15. The other end of the inertia member 15 is provided with a spring retaining portion 15d and a spring guide portion 15e for supporting and guiding the other end of the control spring 16. As shown in FIG. 2, the inertia member 15 is rockably supported on the lock gear 14 by fitting the hole 15a with the shaft 14f of the lock gear 14. At this time, the boss portion 15b of the inertia member 15 is retained by the retaining projection 15g₁ of the fall preventing member 14g, thereby preventing the inertia member 15 from coming off the shaft 14f, as described above.

As shown in FIG. 2, the control spring 16 is fitted at both ends thereof to the respective guide portions 14e and 15e of the lock gear 14 and the inertia member 15 in a state where the inertia member 15 is rockably supported on the shaft 14f. Thus, the control spring 16 is compressedly loaded between the spring retaining members 14d and 15d. Accordingly, the inertia member 15 is constantly biased in the direction α relative to the lock gear 14 by the spring force from the control spring 16, so that it is normally held in a position where it abuts on the first stopper 14h, as shown by the solid line. On the other hand, when the inertia member 15 rotates in the direction β relative to the lock gear 14 against the spring force from the control spring 16, the inertia member 15 assumes a position where it abuts on the second stopper 14i, as shown by the two-dot chain line.

As shown in FIGS. 2 and 3, when the seat belt retractor 1 is in an assembled state, the teeth 13c of the lock gear first cover 13 lie inside the annular flange 14b of the lock gear 14 and in between the flange 14b and the inertia member 15. Since the inertia member 15 is normally held in a position where it abuts on the first stopper 14h, which is shown by the solid line in FIG. 2, the pawl 15c is held in a non-engaging position, which is apart from the teeth 13c. When the inertia member 15 is in a position where it abuts on the second stopper 14i, which is shown by the two-dot chain line in FIG. 2, the pawl 15c assumes a position where it is engageable with a tooth 13c.

If the lock gear 14 rotates in the webbing unwinding direction α when the pawl 15c is in the engageable position, the pawl 15c engages with a tooth 13c, so that the lock gear 14 is prevented from further roatating in the webbing unwinding direction α. If the lock gear 14 rotates in the webbing winding direction β when the pawl 15c is in the engageable position, the pawl 15c passes over the teeth 13c while moving along the gentle slopes of the teeth 13c against the control spring 16. Accordingly, the lock gear 14 is rotatable in the webbing winding direction β.

As shown in FIGS. 18(a), 18(b) and 18(c), the main pawl 17 is formed in a substantially fan-like shape and has a boss portion 17b formed in a portion thereof which acts as a pivot. The boss portion 17b has a through-hole 17a. The main pawl 17 has a pawl portion 17c formed at an end thereof which is remote from the pivot. Further, teeth 17d which are engageable with the teeth 2f of the right-hand side wall 2a of the frame 2 are formed at the distal end of the pawl portion 17c. As shown in FIG. 8(a), the boss portion 17b is pivotably fitted in the third recess 4n of the flange 4b of the reel shaft 4. Accordingly, the main pawl 17 is attached to the reel shaft 4 so as to be pivotable about the boss portion 17b. When it abuts on the step 4q formed on the flange 4b, the main pawl 17 is prevented from further pivoting in the direction α, whereas, when it abuts on the step 4r formed on the flange 4b, the main pawl 17 is prevented from further pivoting in the direction β. In other words, these steps 4q and 4r serve as stoppers for limiting the pivoting motion of the main pawl 17 in the directions α and β, respectively.

When the main pawl 17 abuts on the step 4q, the teeth 17d formed at the distal end thereof lie completely inside the outer peripheral surface of the flange 4b. When the main pawl 17 abuts on the step 4r, the teeth 17d project outwardly from the outer peripheral surface of the flange 4b to reach a position where the teeth 17d are engageable with the teeth 2f of the right-hand side wall 2a of the frame 2, as described later. In addition, the main pawl 17 has a load transfer portion 17e formed at an end of the pawl portion 17c which is remote from the teeth 17d. The load transfer portion 17e is formed from a circular arc which is a part of a circle concentrical with respect to the through-hole 17a and the boss portion 17b.

As shown by the two-dot chain line in FIG. 8(a), the main pawl 17 is attached to the right-hand flange 4b by rotatably fitting the boss portion 17b into the third recess 4n of the reel shaft 4. When the main pawl 17 is attached to the right-hand flange 4b, the pawl portion 17c lies in the second recess 4i, while the load transfer portion 17e abuts on the load bearing surface 4j of the reel shaft 4. Since the load transfer portion 17e and the load bearing surface 4j of the reel shaft 4 are formed from circular arcs of the same circle, the load transfer portion 17e abuts on the load bearing surface 4j of the reel shaft 4 at all times irrespective of the position of the main pawl 17.

Thus, since the load transfer portion 17e abuts on the load bearing surface 4j of the reel shaft 4, a load w applied to the pawl portion 17c of the main pawl 17 is transferred from the load transfer portion 17e to the load bearing surface 4j, as shown in FIG. 8(b), and borne by the reel shaft 4. In such a load bearing structure, since the teeth 17d, which serve as a point of application of load, and the load transfer portion 17e are relatively close to each other, substantially no flexure acts on the main pawl 17, but compression alone acts thereon substantially. Moreover, since the load transfer portion 17e and the load bearing surface 4j are in plane contact with each other, the load is transferred to the reel shaft 4 through a relatively wide area and hence dispersed, so that the stress produced therein is relatively small. Accordingly, the level of strength required for the main pawl 17 is lower than that of the conventional main pawl, and hence the main pawl 17 can be formed by using a relatively lightweight material, e.g., a resin material.

Further, the main pawl 17 has a columnar cam follower 17f projecting from a side thereof which is reverse to the side where the load transfer portion 17e is provided. The cam follower 17f is fitted into the third cam hole 14n of the lock gear 14 so as to be guided along the cam hole 14n.

The pawl spring 18 is accommodated in the first recess 4h of the reelshaft 4 and fitted to the spring guide portion 14q of the lock gear 14 so as to be compressedly loaded between the wall surface of the first recess 4h and the spring retaining portion 14p. Accordingly, the pawl spring 18 constantly biases the main pawl 17 relative to the reel shaft 4 in the webbing unwinding direction α. Therefore, the main pawl 17 is normally held in abutment on the step 4q, which is formed on the flange 4b, by the biasing force of the pawl spring 18.

As shown in FIGS. 19(a), 19(b) and 19(c), the joint pin 19 has a body 19a that is formed with a circular cross-sectional configuration. The body 19s ia formed at the right-hand end thereof (as viewed in FIG. 19(a)) with an arm 19b that extends at right angles to the body 19a. A cam follower 19c having a circular cross-sectional configuration is provided at the distal end of the arm 19b. The cam follower 19c is fitted into the second cam hole 14m of the lock gear 14 so as to be guided along the cam hole 14m. Further, a shaft portion 19d having a rectangular cross-sectional configuration is formed at the other end of the body 19a. The shaft portion 19d is fitted into a hole formed in one end portion of the backup pawl 20 (described later) so as to be unable to rotate relative to the backup pawl 20. Accordingly, when the arm 19b pivots in response to the movement of the cam follower 19c guided along the second cam hole 14m, the body 19a rotates, and the rotation of the body 19a is transferred to the backup pawl 20. Thus, the backup pawl 20 pivots in response to the movement of the cam follower 19c guided along the second cam hole 14m.

As shown in FIGS. 20(a), 20(b) and 20(c), the backup pawl 20 is formed in a substantially fan-like shape and has a boss portion 20b formed in a portion thereof which serves as a pivot. The boss portion 20b has a through-hole 20a of rectangular cross-section. The backup pawl 20 has a pawl portion 20c formed at an end thereof which is remote from the pivot. Further, teeth 20d which are engageable with the teeth 2g of the left-hand side wall 2b of the frame 2 are formed at the distal end of the pawl portion 20c. As shown in FIG. 9(a), the boss portion 20b is pivotably fitted in the fifth recess 4x of the flange 4c of the reel shaft 4. Accordingly, the backup pawl 20 is attached to the reel shaft 4 so as to be pivotable about the boss portion 20b. When the backup pawl 20 abuts on a portion 4z' of the step 4z, formed on the flange 4c, which is located at an end of the outer peripheral edge 4y, the backup pawl 20 is prevented from further pivoting in the direction α, whereas, when it abuts on the step 4A formed on the flange 4c, the backup pawl 20 is prevented from further pivoting in the direction β. In other words, these steps 4z' and 4A serve as stoppers for limiting the pivoting motion of the backup pawl 20 in the directions α and β, respectively. When the backup pawl 20 abuts on the step 41', the teeth 20d formed at the distal end thereof lie completely inside the outer peripheral surface of the flange 4c. When the backup pawl 20 abuts on the step 4A, the teeth 20d project outwardly from the outer peripheral surface of the flange 4c to reach a position where the teeth 20d are engageable with the teeth 2g of the left-hand side wall 2b of the frame 2, as described later. In addition, the backup pawl 20 has a load transfer portion 20e formed at an end of the pawl portion 20c which is remote from the teeth 20d. The load transfer portion 20e is formed from a circular arc which is a part of a circle concentrical with respect to the through-hole 20a and the boss portion 20b.

As shown in FIG. 9(a), when the backup pawl 20 is attached to the left-hand flange 4c, the pawl portion 20c lies in the fourth recess 4u, while the load transfer portion 20e abuts on the load bearing surface 4v of the reel shaft 4. In this case, the load transfer portion 20e abuts on the load bearing surface 4v of the reel shaft 4 at all times irrespective of the position of the backup pawl 20.

Thus, since the load transfer portion 20e abuts on the load bearing surface 4v of the reel shaft 4, a load w' applied to the pawl portion 20c of the backup pawl 20 is transferred from the load transfer portion 20e to the load bearing surface 4v, as shown in FIG. 9(b), and borne by the reel shaft 4. In such a load bearing structure, since the teeth 20d, which serve as a point of application of load, and the load transfer portion 20e are relatively close to each other, substantially no flexure acts on the backup pawl 20, but compression alone acts thereon substantially, in the same way as in the case of the above-described main pawl 17. Moreover, since the load transfer portion 20e and the load bearing surface 4v are in plane contact with each other, the load is transferred to the reel shaft 4 through a relatively wide area and hence dispersed, so that the stress produced therein is relatively small. Accordingly, the level of strength required for the backup pawl 20 is lower than that of the conventional backup pawl, and hence the backup pawl 20 can be formed by using a relatively lightweight material, e.g., a resin material.

As shown in FIGS. 21(a) and 21(b), the lock gear second cover 21 comprises a flat plate portion 21a, a flange 21b formed around the outer peripheral edge of the flat plate portion 21a, an engagement projection 21c that is fitted into a through-hole formed in the right-hand side wall 2a of the frame 2, and an engagement portion 21e that defines a gap 21d into which is fitted the engagement projection 2s formed on the upper end of the right-hand side wall 2a. By fitting the engagement projection 2s into the gap 21d, the engagement portion 21e is engaged with the engagement projection 2s, and by fitting the engagement projection 21c into the engagement hole 2r of the right-hand side wall 2a, the lock gear second cover 21 is removably attached to the right-hand side wall 2a so as to cover the deceleration sensing means 7.

As shown in FIG. 22, the deceleration sensing means 7 has a casing 7a, a lever 7b which is pivotably supported by the casing 7a, and an inertia member 7c which is accommodated in the casing 7a so that when the vehicle is in a normal state, the inertia member 7c is in the position shown by the solid line, whereas, when deceleration exceeding a predetermined value acts on the vehicle, the inertia member 7c tilts to the position shown by the two-dot chain line.

As shown in FIGS. 23(a) and 23(b), the casing 7a is formed in the shape of a container having a rectangular cross-sectional configuration. The bottom of the casing 7a is formed as a portion 7d where the inertia member 7c is mounted. The front and rear walls 7e and 7f of the casing 7a are formed with respective engagement ridges 7g and 7h each having a trapezoidal cross-sectional configuration. More specifically, the engagement ridges 7g and 7h have side walls 7g₁, 7g₂, 7h₁ and 7h₂ which are formed as slant surfaces having the same slope angle as that of the side walls 13j₁, 13j₂, 13k₁ and 13k₂ of the recesses 13j and 13k of the guide members 13h and 13i. As will be clear from FIG. 23(a), one longitudinal end of the engagement ridge 7g is formed in the shape of a slant surface 7g₃. Similarly, one longitudinal end of the other engagement ridge 7h is formed in the shape of a slant surface, although not shown. These engagement ridges 7g and 7h are fitted into the recesses 13j and 13k of the guide members 13h and 13i of the lock gear first cover 13.

The lever 7b is pivotably supported at the rear end thereof by the casing 7a. The forward end of the lever 7b is provided with a pawl 7i which is engageable with a tooth 14c of the lock gear 14.

As shown in FIGS. 24(a), 24(b) and 24(c), the inertia member 7c has a hollow cylinder-shaped small-mass portion 7j formed at the bottom thereof. The inertia member 7c further has a solid frustoconical large-mass portion 7k formed on the upper end of the small-mass portion 7j. The large-mass portion 7k has a larger diameter than that of the small-mass portion 7j. The angle of slope of the outer peripheral surface of the large-mass portion 7k is set so that when the inertia member 7c tilts to a maximum degree, as described later, it substantially coincides with the inner surface of the front wall 7e. In addition, a conical actutating projection 7m is formed on the upper end of the large-mass portion 7k. By forming the inertia member 7c so that the top thereof has a larger mass than that of the bottom thereof, as described above, the inertia member 7c can sense deceleration even more sensitively.

As shown in FIG. 22, the inertia member 7c, which is arranged as described above, is mounted in the mounting portion 7d of the casing 7a. In a normal state, the inertia member 7c mounted in the mounting portion 7d erects perpendicularly to the mounting portion 7d, as shown by the solid line, and the upper end of the actuating projection 7m formed at the top of the inertia member 7c fits in a frustoconical recess 7n formed in the lever 7b. In the normal state, the lever 7b is held in a substantially horizontal position shown by the solid line. In this solid-line position, the lever 7b is placed in a non-engaging position where the pawl 7i does not engage with a tooth 14c of the lock gear 14.

When a predetermined degree of deceleration acts on the vehicle, the inertia member 7c tilts until the outer peripheral surface of the large-mass portion 7k substantially abuts on the inner surface of the front wall 7e, as shown by the two-dot chain line. The tilting of the inertia member 7c causes the actuating projection 7m to push up the lever 7b. Accordingly, the lever 7b pivots to the position shown by the two-dot chain line. In the two-dot chain line position, the lever 7b assumes an engageable position where the pawl 7i is engageable with a tooth 14c of the lock gear 14.

Incidentally, the inertia member 7c is provided with the actuating projection 7m, and by virtue of the presence of the actuating projection 7m, it is possible to obtain a relatively large stroke of the lever 7b with a relatively small angle of inclination of the inertia member 7c. Thus, it is possible to shorten the length of the arm of the lever 7b and hence form the deceleration sensing means 7 in a compact structure.

The deceleration sensing means 7, arranged as described above, is accommodated in the accommodating portion 13g by longitudinally fitting the engagement ridges 7g and 7h into the respective recesses 13j and 13k of the guide members 13h and 13i, which are provided in the accommodating portion 13g, as shown in FIG. 22. At this time, the engagement ridges 7g and 7h can be smoothly fitted into the recesses 13j and 13k because one end of each of the engagement ridges 7g and 7h is formed in the shape of a slant surface, as described above.

In addition, the distance a between the upper and lower side walls 7g₁, 7g₂, 7h₁ and 7h₂ at the respective projecting ends of the engagement ridges 7g and 7h is set longer than the distance b between the upper and lower side walls 13j₁, 13j₂, 13k₁ and 13k₂ of the recesses 13j and 13k at the respective positions corresponding to the projecting end positions of the engagement ridges 7g and 7h. When the engagement ridges 7g and 7h are fitted to the recesses 13j and 13k, the casing 7a is supported by the guide members 13h and 13i relatively rigidly by virtue of the elastic force derived from the elastic deformation of the accommodating portion 13g and the casing 7a. In particular, since the side walls of the engagement ridges 7g and 7h and those of the recesses 13j and 13k are formed in the shape of slant surfaces, wedge effect is obtained between the guide members 13h and 13i and the engagement ridges 7g and 7h, so that the casing 7a is supported by the guide members 13h and 13i even more rigidly.

As shown in FIGS. 25(a), 25(b), and 25(c), the webbing guide 22 has a body 22a which is disposed in between the two side walls 2a and 2b of the frame 2 and which has in its center a hole 22f that is pierced with the webbing 3. The webbing guide 22 further has shafts 22b and 22c which project longitudinally from two longitudinal ends, respectively, of the body 22a and which are slidably fitted into the respective guide holes 2p and 2q of the two side walls 2a and 2b. In addition, the webbing guide 22 has flanges 22d and 22e which similarly project longitudinally from the two ends of the body 22a and which abut on the respective upper end surfaces of the side walls 2a and 2b.

The webbing guide 22 slides along the guide holes 2p and 2q of the side walls 2a and 2b in accordance with the roll diameter of the webbing 3 taken up on the reel shaft 4, thereby allowing the webbing 3 to be smoothly wound on and off. The webbing guide 22 also protects the webbing 3.

Next, the operations of the main pawl 17 and the backup pawl 20 will be explained in detail with reference to FIGS. 26A(I)(a) through 26A(II)(d) and FIGS. 26B(I)(c) through 26B(II)(h). It should be noted that in each of FIGS. 26A and 26B, FIGS. 26A(I)(a) through 26A(II)(d) and FIGS. 26B(I)(e) through 26B(II)(h),the upper part designated by "(I)" in these figures shows the operation of the main pawl 17, whereas the lower part designated by "(II)" in these figures shows the operation of the backup pawl 20. In addition, FIGS. 26A and 26B are schematic views in which the teeth 2f, the teeth 17d and the three cam holes 14k, 14m and 14n at the main pawl (17) side are illustrated on the same plane, and in which both the main pawl 17 and the backup pawl 20 are seen from the right-hand side as viewed in FIG. 1C.

Referring generally to FIG. 26A, the reel shaft 4 (in FIG. 26A are shown only the through-hole 4m, which is pierced with the body 19a of the joint pin 19, and the main pawl 17, which is provided on the reel shaft 4) is constantly biased in the direction β relative to the lock gear 14 (in FIG. 26A are shown only the cam holes 14k, 14m and 14n ) by the spring force of the pawl spring 18 (not shown in FIG. 26A; see FIG. 1A, for example). Therefore, the reel shaft 4 rotates in the direction β relative to the lock gear 14 until the body 19a abuts on the upper end edge of the cam hole 14k, thus reaching a normal state as shown in FIG. 26A(a).

In the normal state, the cam follower 19c of the joint pin 19 abuts on the upper end edge of the cam hole 14m, and the cam follower 17f of the main pawl 17 abuts on the upper end edge of the cam hole 14n. In addition, the teeth 17d of the main pawl 17 are far apart from the teeth 2f of the right-hand side wall 2a, so that the main pawl 17 assumes a non-engaging position where the teeth 17d do not engage with the teeth 2f. On the other hand, the backup pawl 20 assumes the position shown in FIG. 26A(a) in accordance with the angle of rotation of the joint pin 19 that is determined by positions at which the cam followers 19c and 17f abut on the respective upper end edges of the cam holes 14m and 14n. That is, the teeth 20d of the backup pawl 20 are far apart from the teeth 2g of the left-hand side wall 2b , so that the backup pawl 20 also assumes a non-engaging position where the teeth 20d do not engage with the teeth 2g.

When the reel shaft 4 rotates in the direction α relative to the lock gear 14 about the first rotating shaft 4d (not shown in FIG. 26A; see FIG. 7), that is, when the through-hole 4m, which is pierced with the body 19a, rotates in the direction α relative to the first to third cam holes 14k, 14m and 14n of the lock gear 14 about the first rotating shaft 4d, the body 19a and the boss portion 17b of the main pawl 17 move a little downwardly along and relative to the first cam hole 14k, as shown in FIG. 26A(b).

At the same time, the cam follower 17f moves a little downwardly by being guided by the third cam hole 14n. At this time, the boss portion 17b also moves a little leftwardly as viewed in the figure in accordance with the cam profile of the first cam hole 14k, and the cam follower 17f moves a little leftwardly in accordance with the cam profile of the third cam hole 14n. Since the amount of the leftward movement of the cam follower 17f is a little larger than that of the boss portion 17b, the main pawl 17 pivots a little in the direction β. Thus, the teeth 17d approach the teeth 2f.

Further, at the same time, the cam follower 19c moves downwardly by being guided by the second cam hole 14m. Since the cam follower 19c also moves rightwardly in accordance with the cam profile of the second cam hole 14m, the arm 19b pivots a little in the direction α about the body 19a. The pivoting motion of the arm 19b in the direction α causes the body 19a to rotate also a little in the direction α. However, since the reel shaft 4 also rotates in the direction α, the body 19a and the arm 19b do not substantially rotate relative to the reel shaft 4. Accordingly, the backup pawl 20 is held in the non-engaging position, as shown in FIG. 26A(b).

Referring next to FIG. 26A(c), when the reel shaft 4 further rotates in the direction α relative to the lock gear 14, the body 19a and the boss portion 17b further move downwardly and leftwardly along the first cam hole 14k. At the same time, the cam follower 17f further moves a little downwardly by being guided by the third cam hole 14n. Since the amount of the further leftward movement of the cam follower 17f is a little larger than that of the boss portion 17b, the main pawl 17 further pivots a little in the direction β, so that the teeth 17d further approach the teeth 2f.

Further, at the same time, the cam follower 19c further moves a little downwardly and leftwardly by being guided by the second cam hole 14m. At this time, since the cam follower 19c also moves a little downwardly and leftwardly in accordance with the cam profile of the second cam hole 14m, the arm 19b does not substantially pivot. However, since the reel shaft 4 further moves in the direction α, the body 19a and the arm 19b rotate in the direction β relative to the reel shaft 4. Thus, the backup pawl 20 pivots a little in the direction β relative to the reel shaft 4, so that the teeth 20d approach the teeth 2g.

Referring to FIG. 26A(d), when the reel shaft 4 further rotates in the direction α relative to the lock gear 14, the main pawl 17 further pivots a little in the direction β relative to the reel shaft 4 in the same way as the above, so that the teeth 17d further approach the teeth 2f to a substantial degree. Similarly, the backup pawl 20 further pivots a little in the direction β, so that the teeth 20d approach the teeth 2g.

Referring to FIG. 26B(e), when the reel shaft 4 further rotates in the direction α relative to the lock gear 14, the main pawl 17 and the backup pawl 20 further pivot in the direction β relative to the reel shaft 4 in the same way as the above. Accordingly, the teeth 17d move to a position where they are engageable with the teeth 2f. In addition, the backup pawl 20 further pivots a little in the direction β, so that the teeth 20d further approach the teeth 2g to a substantial degree.

As shown in FIG. 26B(f), when the reel shaft 4 further rotates in the direction α relative to the lock gear 14, the teeth 17d further approach the teeth 2f by a set amount. However, the teeth 17d will not approach the teeth 2f any further. When the reel shaft 4 further pivots in the direction α in this state, the tooth 17d₁ among the teeth 17d of the main pawl 17, which is the forefront when the main pawl 17 pivots in the direction α, comes in contact with the steep slope of a tooth 2f. This position of the main pawl 17 is the standby position where the teeth 17d of the main pawl 17 begin to engage with the teeth 2f of the right-hand side wall 2a. When the reel shaft 4 further rotates in the direction α after the tooth 17d₁ has come in contact with the steep slope of the tooth 2f, the tip of the tooth 17d₁ is guided toward the bottom of the tooth 2f by the steep slope of the tooth 2f, causing the main pawl 17 to pivot in the direction β.

Thus, when the reel shaft 4 further rotates in the direction α relative to the lock gear 14, the tips of the teeth 17d come in contact with the respective bottoms of the teeth 2f, so that the teeth 17d of the main pawl 17 are completely engaged with the teeth 2f of the right-hand side wall 2a, as shown in FIG. 26B(g). Thus, the main pawl 17 reaches the lock position. The motion of the main pawl 17 from the standby position to the lock position is not caused by the cam hole 14n, but realized by the guiding action of the steep slopes of the teeth 2f. With this motion, the main pawl 17 performs a self-lock action.

On the other hand, when the teeth 17d of the main pawl 17 become completely engaged with the teeth 2f of the right-hand side wall 2a, the backup pawl 20 assumes a position where the tooth 20d₁ among the teeth 20d, which is the forefront during pivoting in the direction α, is in contact with the steep slope of a tooth 2g. Thus, the backup pawl 20 reaches the standby position where the teeth 20d of the backup pawl 20 begin to engage with the teeth 2g of the left-hand side wall 2b.

As shown in FIG. 26B(h), when the reel shaft 4 further rotates in the direction α relative to the lock gear 14, the complete engagement between the teeth 17d and 2f is maintained. In the meantime, the backup pawl 20 performs a self-lock action similar to that of the main pawl 17 by being guided by the steep slopes of the teeth 2g. Thus, the backup pawl 20 becomes completely engaged with the teeth 2g of the left-hand side wall 2b to reach the lock position.

Thus, the engagement of the teeth 20d of the backup pawl 20 with the teeth 2g begins with a little delay with respect to the engagement of the teeth 17d of the main pawl 17 with the teeth 2f.

The following is a more specific description of the motions of the main pawl 17 and the lock gear 14 during the self-lock action of the main pawl 17 performed from the standby position, that is, the shift from the position shown in FIG. 26B(f) to the position shown in FIG. 26B(g), together with the cam profile of the third cam hole 14n and the configuration of the teeth 2f of the right-hand side wall 2a whereby the motions of the main pawl 17 and the lock gear 14 are realized.

FIGS. 27(a) and 27(b) are enlarged views of FIGS. 26B(f) and 26B(g), respectively.

First, the cam profile of the third cam hole 14n for controlling the pivoting of the main pawl 17 when the reel shaft 4 rotates in the direction α relative to the lock gear 14 will be explained. In the non-engaging position of the main pawl 17, shown in FIG. 26A(a), the cam follower 17f is at the uppermost end position in the third cam hole 14n. The cam profile of the third cam hole 14n is designed so that when the reel shaft 4 rotates in the direction α relative to the lock gear 14, the cam follower 17f lowers from the uppermost end position in the third cam hole 14n by being guided by the first guide cam surface 14n₁ of the third cam hole 14n, causing the main pawl 17 to pivot in the direction β until it reaches the standby position, shown in FIG. 27(a), thereby allowing the teeth 17d to approach the teeth 2f of the right-hand side wall 2a.

Further, the cam profile of the third cam hole 14n is designed so that when the cam follower 17f has reached the position in the third cam hole 14n that is shown in FIG. 27(a), the third cam hole 14n does not guide the cam follower 147f any longer even if the reel shaft 4 rotates in the direction α relative to the lock gear 14. With the above-described cam profile, the third cam hole 14n does not allow the tips of the teeth 17d to reach the bottoms of the teeth 2f.

When the main pawl 17 shifts from the standby position, shown in FIG. 27(a), to the lock position, that is, the completely engaged position, shown in FIG. 27(b), the main pawl 17 performs the self-lock action by virtue of the guiding action of the steep slopes of the teeth 2f, as described above. For this self-lock action, the cam profile of the third cam hole 14n is designed so that the cam follower 17f causes the lock gear 14 (represented by the first to third cam holes 14k, 14m and 14n in FIG. 27) to rotate a little reversely in the direction β through the second guide cam surface 14n₂ of the third cam hole 14n. By virtue of the above-described cam profile, when the main pawl 17 becomes completely engaged with the teeth 2f, the pawl 7i of the lever 7b in the deceleration sensing means 7 can be disengaged from the tooth 14c of the lock gear 14. Accordingly, it is possible to prevent occurrence of end lock.

Thus, the third cam hole 14n comprises a control portion for controlling the action of the main pawl 17, which is comprised of the first guide cam surface 14n₁ that guides the cam follower 17f from the non-engaging position at the upper end of the cam hole 14n, shown in FIG. 26A(a), to the standby position, shown in FIG. 26B(f), and a control portion for controlling the reverse rotation of the lock 14n 2 that transfers operating force from the cam follower 17f to the lock gear 14 when the cam follower 17f shifts from the standby position, shown in FIG. 26B(f), to the lock position, shown in FIG. 26B(g), thereby causing the lock gear 14 to rotate reversely in the webbing winding direction.

On the other hand, the steep slopes of the teeth 2f of the right-hand side wall 2a have a slope angle θ [angle of the steep slope of each tooth 2f to an imaginary straight line γ connecting together a contact portion δ of the steep slope of the tooth 2f, which is in contact with the tooth 17d₁, and the center ε of pivoting motion of the main pawl 17, as shown in FIG. 27(a)] set so that the main pawl 17 can perform a self-lock action from the standby position, shown in FIG. 27(a), to the completely engaged position, shown in FIG. 27(b).

Similarly, the steep slopes of the teeth 2g of the left-hand side wall 2b have a slope angle set so that the backup pawl 20 can perform a self-lock action.

The following is a description of the cam profile of the second cam hole 14m for controlling the pivoting motion of the backup pawl 20 when the reel shaft 4 rotates in the direction α relative to the lock gear 14.

The cam profile of the second cam hole 14m is designed so that the backup pawl 20 performs an action similar to that of the main pawl 17 with a delay with respect to the action of the main pawl 17, as shown in FIGS. 26A and 26B. Particularly, the cam profile of the second cam hole 14m is designed so that when the main pawl 17 shifts from the standby position, shown in FIG. 26B(f), to the lock position, shown in FIG. 26B(g), that is, when the main pawl 17 reaches the lock position by performing a self-lock action, the backup pawl 20 reaches the standby position, as shown in FIG. 26B(g).

By virtue of the cam profile of the second cam hole 14m, the main pawl 17 first reaches the lock position where the teeth 17d of the main pawl 17 become completely engaged with the teeth 2f of the right-hand side wall 2a, and at this time the backup pawl 20 is set in the standby position. Thereafter, with a little delay, the backup pawl 20 reaches the lock position where the teeth 20d thereof are completely engaged with the teeth 2g of the left-hand side wall 2b. Accordingly, after the teeth 17d have become completely engaged with the teeth 2f, the teeth 20d are completely at least either the engagement between the main pawl 17 and the teeth 2f or the engagement between the backup pawl 20 and the teeth 2g is surely made without an engagement failure.

Next, the operation of the seat belt retractor in this embodiment, arranged as described above, will be explained.

Normal State Where No Deceleration Exceeding a Predetermined Value Acts on the Vehicle

In this state, the inertia member 7c of the deceleration sensing means 7 does not tilt forwardly. Therefore, the lever 7b is held in the solid-line position as shown in FIG. 2, and the pawl 7i is placed in the non-engaging position, which is apart from the teeth 14c of the lock gear 14. Similarly, the pawl 15c of the inertia member 15, the main pawl 17 and the backup pawl 20 are held in the respective non-engaging positions, as shown in FIGS. 2 and 4.

Accordingly, in this state the seat belt retractor 1 mainly performs an operation based on the action of the biasing force application means 5. That is, the reel shaft 4 is biased in the webbing winding direction β by the spring force of the power spring 8 of the biasing force application means 5 so as to wind up the webbing 3.

When the Seat Belt is Not Fastened to the Occupant's Body

In this state, a tongue (not shown), which is attached to the webbing 3, is separate from a buckle member (not shown). Accordingly, the webbing 3 has been wound up by the spring force of the power spring 8, as described above.

When the Webbing is Unwound

When the occupant unwinds the webbing 3 in order to fasten it to his/her body, the reel shaft 4 and the bush 9 rotate in the webbing unwinding direction α in response to the unwinding of the webbing 3. Consequently, the power spring 8 is gradually wound up.

When the Occupant Takes His/Her Hand Off the Webbing After Connecting Together the Tongue and the Buckle Member

At the time when the occupant connects together the tongue and the buckle member, the webbing 3 has been unwound in excess of the length of the webbing 3 unwound when the occupant has it fastened to his/her body in a normal state. Therefore, when the occupant takes his/her hand off the webbing 3 after connecting together the tongue and the buckle member, the webbing 3 is wound up by the spring force of the power spring 8 until it fits to the occupant's body. The spring force of the power spring 8 is properly determined in advance so that the webbing 3 will not give a sensation of pressure to the occupant. During the running of the vehicle, the seat belt retractor 1 maintains this state unless deceleration exceeding a predetermined value acts on the vehicle.

When Deceleration Exceeding a Predetermined Value Acts on the Vehicle

When deceleration exceeding a predetermined value acts on the vehicle during the running due to a sudden braking operation or other emergency operation, both the seat belt lock activating means 6 and the deceleration sensing means 7 operate. As a first stage of the operation, the inertia member 7c of the deceleration sensing means 7 moves forwardly (the position shown by the two-dot chain line in FIG. 2) by inertia, so that the lever 7b pivots upwardly to reach the position shown by the two-dot chain line in FIG. 2. Consequently, the pawl 7i of the lever 7b assumes an engageable position where it is engageable with a tooth 14c of the lock gear 14. In the meantime, the occupant's body is urged to move forwardly by the deceleration acting on the vehicle to a degree higher than a predetermined value, thus causing the webbing 3 to be unwound. The unwinding of the webbing 3 causes both the reel shaft 4 and lock gear 14 to rotate in the unwinding direction α.

However, since a tooth 14c of the lock gear 14 engages with the pawl 7i immediately, the lock gear 14 is immediately stopped from rotating in the unwinding direction α. As a result, the reel shaft 4 alone continuously rotates in the unwinding direction α. Thus, the reel shaft 4 rotates in the direction α relative to the lock gear 14.

The relative rotation of the reel shaft 4 in the direction α causes the main pawl 17 to pivot in the direction β relative to the reel shaft 4 and to engage with the teeth 2f to thereby reach the lock position, as a second stage of the operation, as shown in FIGS. 26A and 26B. At this time, when the main pawl 17 shifts from the standby position to the lock position, the lock gear 14 rotates a little reversely in the webbing winding direction β. When the main pawl 17 reaches the lock position, the backup pawl 20 reaches the standby position. Thereafter, with a little delay, the backup pawl 20 engages with the teeth 2g to reach the lock position.

Thus, the reel shaft 4 is locked from rotating in the webbing unwinding direction α.

As a result, unwinding of the webbing 3, which would otherwise be caused by the inertial forward movement of the occupant's body, is surely prevented. Thus, the occupant's body is reliably restrained and protected. Further, at this time, the lock gear 14 rotates a little reversely in the webbing winding direction β, causing the pawl 7i of the deceleration sensing means 7 to disengage from the tooth 14c of the lock gear 14, thus bringing the lock gear 14 into a free state. Therefore, the reel shaft 4 can rewind the webbing 3 with ease.

When Unwinding Force Suddenly Acts on the Webbing

When such a situation occurs, the webbing 3 is suddenly unwound, so that the reel shaft 4, the lock gear 14 and the inertia member 15 are suddenly urged to rotate in the webbing unwinding direction α. However, since the spring force of the control spring 16 is not so strong, the control spring 16 contracts, so that the inertia member 15 has an inertia delay. That is, the inertia member 15 not only revolves in the webbing unwinding direction α together with the lock gear 14 but also rotates in the direction β relative to the lock gear 14.

The rotation of the inertia member 15 causes the pawl 15c to move to the engageable position, where it abuts on the second stopper 14i, and engage with a tooth 13c of the lock gear first cover 13, as shown by the two-dot chain line in FIG. 2. Consequently, the revolution of the inertia member 15 and the rotation of the lock gear 14 in the webbing unwinding direction α are stopped. Accordingly, the reel shaft 4 alone rotates in the webbing unwinding direction α. Thus, the reel shaft 4 rotates in the direction α relative to the lock gear 14, as described above.

The relative rotation of the reel shaft 4 in the direction α causes the main pawl 17 to pivot and engage with the teeth 2f, and thereafter, with a little delay, the backup pawl 20 engages with the teeth 2f, in the same way as the above. Thus, the reel shaft 4 is locked from rotating in the webbing unwinding direction α. As a result, unwinding of the webbing 3, which would otherwise be caused by the inertial forward movement of the occupant's body, is surely prevented. Thus, the occupant's body is reliably restrained and protected.

In this case also, the lock gear 14 rotates a little reversely in the webbing winding direction β, causing the pawl 15c of the inertia member 15 to disengage from the tooth 13c of the lock gear first cover 13, thus bringing the lock gear 14 into a free state. Therefore, the reel shaft 4 can rewind the webbing 3 with ease.

It should be noted that the present invention is not necessarily limited to the above-described embodiment and that various changes and modifications may be imparted thereto. For example, although in the foregoing embodiment the present invention is applied to a frame lock type retractor wherein the reel shaft is locked by engaging pawls provided on the reel shaft with teeth formed on the frame, the present invention is also applicable to conventional retractors, e.g., a frame lock type retractor wherein teeth formed on the reel shaft are engaged with teeth formed on the frame, or a retractor wherein pawls provided on the frame are engaged with teeth formed on the reel shaft.

Further, although in the foregoing embodiment the biasing force application means 5 is not provided with a comfort device, the present invention may also be applied to a seat belt retractor that is provided with a comfort device.

As will be clear from the foregoing description, according to the biasing state maintaining device for a biasing force application means used in a seat belt retractor according to the present invention, the rotation preventing member is attached to the biasing force application means, which is in a state of subassembly, so that the pair of rotation preventing arms thereof pierce through the pair of small holes of the cover, two of the grooves of the bush and the pair of small holes of the spring casing, thereby enabling the power spring to be readily held in a wound-up state.

Further, since the cover need not be provided with a large hole, there is no need for a lid which has heretofore been needed to close such a hole in the conventional seat belt retractor, and hence it is unnecessary to carry out an operation for mounting a lid. Thus, it is possible to reduce the number of parts required as well as the number of manufacturing operation steps required in comparison to the conventional seat belt retractor.

Further, according to the present invention, since the rotation preventing member is formed from a single elastic wire material, the biasing state maintaining device can be formed with ease and at reduced cost. 

What we claim is:
 1. In a biasing force application means used in a seat belt retractor, which includes a bush fitted to a reel shaft so as to be unable to rotate relative to it, a spring casing for accommodating said bush, a cover for covering said spring casing, and a spring accommodated in said spring casing and retained at an inner end thereof by said bush and at an outer end thereof by said spring casing so that said reel shaft is biased by spring force from said spring so as to rotate in a direction for winding up a webbing,a device for maintaining a biasing state of said biasing force application means, said device comprising a pair of small holes formed in said spring casing, a predetermined number of grooves formed in said bush, a pair of small holes formed in said cover, and a rotation preventing member formed from an elastic material and having a pair of rotation preventing arms capable of piercing through said small holes and grooves, said rotation preventing member being attached to said biasing force application means in a state where said spring has been wound up by a predetermined amount so that said pair of rotation preventing arms pierce through said small holes of said spring casing, two of said grooves of said bush and said pair of small holes of said cover, thereby maintaining said spring in the wound-up state.
 2. A biasing state maintaining device according to claim 1, wherein said rotation preventing member comprises a spring pin formed by bending a single elastic wire material in a U-shape. 